DE202017101713U1 - Conduit for SCR applications - Google Patents

Abstract

Conduit system for SCR applications, comprising a connection connector (1) with a connection channel (2) to which at a channel end via a connection portion (3), a first fluid line (4) is connected to a tank (5) or with a compressed air unit (6) is alternatively connected, wherein the tank (5) is filled with a urea solution, and the connection connector (1) at the other end of the through-channel (2) via a connector (7) and a connector (8) with a metering unit (8a ) is connectable to the injection of the urea solution, characterized in that on the connection channel (2) a second fluid line (9) via a connection portion (10) is connected, which is also connected to the tank (5).

Description

The present invention relates to a line system for SCR applications, comprising a connection connector with a connection channel to which at a channel end via a connection portion a fluid line is connected, which is connected to a tank or to a compressed air unit alternatively, wherein the tank is filled with a urea solution is, and the connection connector at the other end of the passageway via a connector and a connector with a metering unit for injecting the urea solution is connectable.

The maximum urea temperature in piping systems for SCR applications is limited due to chemical decomposition processes. Usually, a maximum temperature of +80 ° C to +100 ° C is specified. At the same time, the ambient temperatures of SCR lines in the vehicle have increased significantly as the location of the urea dosing has been brought closer and closer to the engine. Externally applied heat protection measures are only partially applicable (for example against radiant heat). At permanently elevated ambient temperatures and the heat protection devices are eventually warmed through, so that heats up the urea solution. The fact that the urea volume flow in the piping system is very small additionally promotes the heating of the urea solution.

Furthermore, SCR metering systems are known, which empty the SCR line after completion of the metering operation by means of compressed air in the direction of an exhaust pipe of the vehicle. As a result, a certain amount of urea enters the exhaust pipe at each discharge process. Since the motor of the motor vehicle is already switched off at this time, the urea solution in the exhaust pipe can no longer be used and is deposited there.

The present invention is based on the object to avoid the disadvantages of the known SCR line systems, as explained above.

According to the invention this is achieved in that a second fluid line is connected to the connection channel via a connection section, which is also connected to the tank. As a result, according to the invention a two-pipe system is formed, which causes an increased urea volume flow. The pump, which is integrated in the tank, for example, therefore promotes more urea solution than is needed for the injection for pollutant conversion. This increase in the volume flow shortens the residence time of the urea solution in the piping system, which reduces heating. In addition, an increased volume flow causes an internal cooling of the connection connector and its individual parts, such as the sealing rings contained therein.

In a further embodiment of the invention, it may be expedient that in the connection channel of the connector a valve body of a valve integrated in the connector between two positions of the valve body is movably guided or displaceable, wherein in a first position of the valve body located in the tank urea solution through the Valve body is passed into the connector for forwarding into the dosing unit, and the second fluid line is closed, and in a second valve body position, the first fluid line and the second fluid line are connected via the valve body for circulation of the urea solution, and no introduction of the urea solution in the Dosing unit over the valve body takes place. The displaceability of the valve body can be translational and / or rotational. Thus, by means of the valve body, the flow direction of the urea solution can be influenced in a targeted manner. The actuation of the valve body is optionally carried out via an electromagnet which acts on the valve body from the outside through the connecting piece. As a result, an actuation of the valve body without opening the fluidic circuit is possible. The valve body may for example be designed as a cylinder having different, distributed over the circumference, grooves and channels and / or holes. As a result of the rotation of the valve body or in particular via different translational switching positions, the flow direction can thus be changed. As a result, the urea passage can be switched on or off in order to be able to react optimally to each operating state. The thus configured line system according to the invention can not only change the flow direction of the urea solution, but also from the outside via the first fluid line supplied compressed air, for example, allows an empty bubbles of the first fluid line, the SCR line, via the second fluid line into the tank.

Furthermore, it may also be expedient that in the connection channel of the connection connector, in which the valve body is adjustably guided between two valve body positions, both the urea solution located in the tank via the first fluid line through the valve body is introduced into the dosing unit in a first valve body position, as also a circulation of the urea solution through the Valve body is provided through the second fluid line back into the tank, and in a second valve body position, only a circulation from the first fluid line through the valve body through the second fluid line is carried back into the tank.

Conveniently, an orifice plate is installed within the duct of the connection connector to the tank, which is essentially formed by the second fluid conduit, which returns the urea solution to the tank, so that sufficient pressure for injection into the metering device is established via the connector within the connection channel of the connector ,

It is also within the scope of the invention to provide three switching positions of the valve body, wherein the third switching position then expediently takes place by a rotation, in such an embodiment then three functions would be possible, namely the dosing plus the circulation, only the circulation and a switching position, in the conduit system is completely closed, so no dosing and no circulation can take place.

In the case of the electromagnetic valve advantageously used according to the invention, the actuator is located outside the fluidic region, for example it can be clipped onto the outside of the connection connector. As a result, the fluidic area is untouched, which reduces the risk of leaks. In addition, no complex sealing measures must be provided for moving parts of the connection connector. Advantageously, the valve body is secured against twisting or slipping within the fluid connector, so that the flow channels within the valve body are congruent with the through holes of the connection sections for the fluid lines in each switching position under all operating conditions. This can be realized, for example, by a tongue and groove connection between the valve body and the housing of the connection connector, so that the valve body is translationally freely movable in the direction of its longitudinal axis, but is blocked in rotation.

As a material for the valve body, a material resistant to urea must be suitably used. In this case, it is furthermore advantageous according to the invention if at least the inner part of the valve body consists of a ferromagnetic material which can be used with an electromagnet as the actuating element. Furthermore, it may be advantageous if the valve body is coated on its outer surface to achieve good sliding properties and media resistance with a suitable material.

• - Kühlung des Anschlussverbinders sowie dessen Bauteile und Schutz vor Überhitzung und beschleunigter Materialalterung,
• - gezieltes, von außen steuerbares Entleeren des Leitungssystems nach dem Ausschalten des Motors sowie Entleerung der Restmenge aus dem Leitungssystem zurück in den Tank, so dass eine Entleerung in das Abgasrohr entfallen kann.

By means of the line system according to the invention, a lowering of the temperature of the medium in the line system can be effected, the following advantages being achieved:

• - Cooling of the connector and its components and protection against overheating and accelerated material aging,
• - Targeted, externally controllable emptying of the pipe system after switching off the engine and emptying of the residual amount from the pipe system back into the tank so that emptying into the exhaust pipe can be omitted.

Furthermore, the invention relates to a connection connector for use in the conduit system according to the invention. as claimed in particular in claims 4 to 20.

• 1 eine Prinzipdarstellung eines erfindungsgemäßen Leitungssystems,
• 2, 3, 3a, 4, 4a, 5, 5a, 6, 6a Längsschnitte verschiedener Ausführungsformen durch ein erfindungsgemäßes Leitungssystem bzw. eines darin befindlichen erfindungsgemäßen Anschlussverbinders,
• 5b einen Querschnitt entsprechend der Schnittlinie V-V in 3 und 5.

Reference to the embodiments illustrated in the accompanying drawings, the invention is explained in detail. Show it:

• 1 a schematic diagram of a conduit system according to the invention,
• 2 . 3 . 3a 4, 4a, 5, 5a, 6, 6a show longitudinal sections of various embodiments through a line system according to the invention or a connection connector according to the invention located therein,
• 5b a cross section corresponding to the section line VV in 3 and 5 ,

In the various figures of the drawing, like parts are always provided with the same reference numerals.

For the following description is expressly claimed that the invention is not limited to all or more features of described combinations of features, but each individual feature part of the embodiment also detached from all other described in connection therewith partial features on its own and in combination with other features and also independent of the combinations of features and relationships of the claims an inventive meaning in conjunction with the subject of the claim 1 to have.

The present invention relates to a conduit system for SCR applications, see 1 and 2 comprising a terminal connector 1 with a connection channel 2, at which at a channel end via a connection section 3 a first fluid line 4 connected to a tank 5 and with a compressed air unit 6 alternatively via a switching valve 5a connected, the tank 5 filled with a urea solution, and the connection connector 1 at the other end of the connection channel 2 via a connection piece 7 and via a connector 8th with a dosing unit 8a for injecting the urea solution into an exhaust pipe 8b is connectable. Furthermore, it is provided that to the connection channel 2 a second fluid line 9 , which serves in particular as return, via a connection section 10 connected is. In this case, in particular, the flow cross-section of the connection section 10 at least partially smaller than the flow cross section of the connection section 3 for the first fluid line 4 , Such a narrowing of the flow cross-section of the connection section 10 for the second fluid line 9 is especially as a throttle point 11 formed, for example, as a separate component in the connection section 10 can be used.

The connection connector 1 has a connector body formed as a plastic molding 12 on, the internal connecting channel 2 includes, as well as the connection section 3 for the first fluid line 4 , as well as the connector 7 for the connector 8th and the connection section 10 for the second fluid line 9 , The connection channel 2 is at the connector 7 closed opposite inner end. The connector body 12 can preferably be electrically heated, for which purpose, for example, a spirally wound heating wire can be arranged on its circumference, the z. B. through the connector body 12 trained grooves 12a is guided in its winding course. These grooves can, for example, by adjacent extensions 12b be formed.

The connection sections 3 and 10 are advantageously provided with through holes 15, into which the fluid lines 4 and 9 be plugged, so this is a socket-like design of the connection sections 3 and 10 is. The attachment of the fluid lines 4 and 9 can, for example, within the passage openings 15 by a cohesive connection, for example by gluing or welding, in particular laser welding done.

At the fluid lines 4 and 9 are expediently plastic pipes with an internal passage 4a . 9a , which may also be provided on its outer circumference with electrical heating elements, in particular heating wires.

Conveniently, in a receiving opening 7a of the connector 7 a connecting body 17 plugged in, in which a plug pin 19 in the inserted state by means of holding means 20 is fixed, and by an operation in particular spreading of the holding means 20 can the plug pin 19 from the connecting body 17 be pulled out.

In the 2 illustrated embodiment of the conduit system according to the invention is suitable that in the tank 5 urea solution present through the first fluid line 4 over the connection channel 2 in the fitting 7 and to the dosing unit 8a and simultaneously via the second fluid line 9 back to the tank 5 can flow. Thus, on the one hand a circulation of the urea solution is possible and on the other hand a simultaneous injection of the urea solution by means of the metering unit 8a ,

For example, a cooling effect can be achieved by the circulation of the urea solution. Will the first fluid line 4 from the tank 5 disconnected, and a connection to the compressed air unit 6 produced, can blow out the urea solution in the system via the dosing unit 8a take place and on the other hand, a drain in the second fluid line 9 urea solution in the tank 5 ,

In the 3 and 3a a further embodiment of a conduit system according to the invention is shown. Here are the same parts as in 2 marked with the same reference numerals. In the illustrated embodiment of the conduit system is in the connection channel 2 of the connection connector 1 in its connector body 12 a valve body 21 one in the connection connector 1 integrated valve between two positions of the valve body 21 slidably guided. In a first position of the valve body 21 , please refer 3 , that will be in the tank 5 urea solution through the valve body 21 through into the fitting 7 conveyed to the metering unit for forwarding, wherein the second fluid line 9 is closed and in a second valve body position of the valve body 21 , please refer 3a , is the first fluid line 4 and the second fluid line 9 over the valve body 21 for a circulation of the urea solution connected to each other, and there is no introduction of the urea solution into the dosing unit 8a over the valve body 21 , The preferably cylindrical valve piston 21 is in the connection channel 2 in the longitudinal direction of the connection channel 2 guided translationally displaceable between the two valve body positions, and that of the first the connector 7 close position and in the second, the connector 7 distant position and vice versa. Appropriately, it is in the valve body 21 to a component of an electromagnetic valve, wherein the valve body 21 against one in the connection channel 2 arranged compression spring 21a in the from the connector 7 Remote position can be moved, and from this position, he is by the force of the compressed compression spring 21a moved back into the fitting 7 close position. Advantageously, the valve body 21 in the connector body 12 via a tongue and groove connection 22 secured against twisting, see 5b ,

It may be useful if in the valve body 21 one in the longitudinal direction of the valve body 21 extending, closed at its end longitudinal bore 23 is formed and two transverse bores 24 . 25 , which are arranged so that they viewed in the longitudinal direction of the valve body 21 are arranged one behind the other and on the one hand in the longitudinal bore 23 and on the other hand on the outer circumference of the valve body 21 , The closure of the longitudinal bore 23 takes place at one end, for example by a closure plate 14 or similar.

Conveniently, between the two transverse bores 24 . 25 on the circumference of the valve body 21 a peripheral seal 26 arranged. In the valve body 21 is a longitudinally extending through this connecting hole 27 intended. Here are the two transverse holes 24 . 25 in the valve body 21 arranged such that in the second valve body position their outlet openings on the circumference of the valve body 21 each with the passage opening 15 one of the connection sections 3 . 10 the two fluid lines 4 . 9 connected is. In the first valve body position are the transverse bores 24 . 25 closed, and the passage opening 15 the one with the tank 5 connected connection section 3 opens in a between the valve body 21 at its end remote from the metering unit fitting and the opposite wall of the connector body 12 trained cavity 29 in which also the connection hole 27 ends.

According to 4 . 4a may be an alternative embodiment, wherein like parts 2 . 3 . 3a are provided with the same reference numerals that instead of the two transverse bores 24 . 25 on the circumference of the valve body 21 a circumferential groove 30 is formed, which has such a length that the two through holes 15 the connection sections 3 . 10 for the fluid lines 4 . 9 in the raised second position of the valve body 21 in it, leaving a circulation between the two fluid lines 4 . 9 takes place, and a fluid introduction to the dosing unit can not be done. In this case, the valve body 21 also the connecting bore extending through it 27 up, see 3 , and the circumferential groove 30 is dimensioned such that in the first valve body position, the passage opening 15 of the connection section 3 for the first fluid line 4 in the cavity 29 ends, see 3 . 3a , and the passage opening 15 of the connection section 10 for the second fluid line 9 in the circumferential groove 30 , On both sides of the circumferential groove 30 are in the valve body 21 preferably circumferential seals 13 arranged. This embodiment simplifies the manufacture of the valve body 21 and favors the cooling effect. Thus, for example, no tongue and groove connection is required and a throttle is not necessary.

Furthermore, an inventive conduit system in modification of 3 . 3a be so formed, see 5 . 5a that in the connection duct 2 of the connection connector 1 the valve body 21 is guided so adjustable between the two valve body positions that in the second valve body position, see 5a , both in the tank 5 urea solution through the valve body 21 through into the dosing unit 8a is introduced as well as a circulation of the urea solution through the valve body 21 through the second fluid line 9 back to the tank 5 takes place and in the first valve body position exclusively a circulation of the first fluid line 4 through the valve body 21 through the second fluid line 9 back into the tank 5 takes place. For this purpose, it is advantageous if four transverse bores in the connection connector 24 . 24a . 25 . 25a in the valve body 21 , which are behind each other, are formed. These four cross holes 24 . 24a . 25 . 25a are each one-sided with the longitudinal bore 23 in the valve body 21 connected and on the other hand on the circumference of the valve body 21 formed ending, in particular between the respective second and third transverse bore 24a . 25 on the circumference of the valve body 21 the peripheral seal 26 is trained. Here is the first and second transverse bore 24 . 24a , each removed from the connector 7 lie, with the first fluid line 4 that from the tank 5 comes, and the third and fourth transverse bore 25, 25 a with the second fluid line 9 leading to the tank 5 the fluid returns, depending on the position of the valve body 21 connectable. Here is the valve body 21 suitably adapted so that in the second, from the connector 7 for the dosing unit remote position of the valve body 21 the first cross hole 24 with one in the wall of the connector body 12 trained groove-shaped, open-edged channel 32 is connected, extending in the longitudinal direction of the cavity 29 extends and to the cavity 29 is open, as well as between the end face of the valve body 21 and the opposite of this inner end surface of the connection channel 2 runs. The cavity 29 is over the connection hole 27 in the valve body 21 with the connection channel 2 connected, allowing a flow through the valve body 21 from the connection section 3 for the first fluid line 4 until the metering module is possible. The fourth transverse bore 25a is with the through hole 15b of the connection section 10 for the connection of the second fluid line 9 connected, and the third transverse bore 25 is through the wall of the connector body 12 locked.

Furthermore, it may be advantageous according to the invention when the valve body 21 is adapted such that in the first valve body position of the valve body 21 the first cross hole 24 with the through hole 15a of the connection section 3 for the first fluid line 4 communicates, and the third transverse bore 25 in the valve body 21 with the through hole 15b of the connection section 10 for the connection of the second fluid line 9 is connected, and the other cross holes in the valve body 21 through the wall of the connector body 12 are closed.

In a further embodiment, it may be appropriate, see 6 . 6a , wherein the same parts as in the 3 to 5 are provided with the same reference numerals when the cross section of the through hole 15b of the connection section 10 for the second fluid line 9 is greater than the cross section of the fourth transverse bore 25a in the valve body 21 , and the valve body 21 adjusted so that in the second position, 6a , the valve body 21 his second transverse bore 24a with the through hole 15a of the connection section 3 for the first fluid line 4 communicates, as well as the fourth transverse bore 25a with the through hole 15b of the second fluid line 9 over a connecting gap 33 with the connection channel 2 in the area of the connection piece 7 is designed for the metering module. It is advantageous if the valve body 21 is adapted such that in its first valve body position, the first transverse bore 24 of the valve body 21 with the through hole 15a of the connection section 3 for the first fluid line 4 communicates, as well as the third transverse bore 25 of the valve body 21 with the passage bore 15b of the connection section 10 for the second fluid line 9 ,

In this embodiment, in the second valve body position, the urea solution from the tank 5 over the second cross hole 24a and through the valve body 21 through and the fourth transverse bore 25a as well as the connection gap 33 in the connection channel 2 and the connector 7 to the dosing unit 8a flow and at the same time through the passage opening 15b in the second fluid line 9 in the tank 5, so that a circulation of the urea solution takes place during dosing. In the first valve body position only one circulation is possible. In this position, when connecting to the compressed air unit, the blowing out of the urea solution from the piping system and the connection connector 1 in the tank 5 respectively.

1. 1. Eindosieren und gleichzeitige Zirkulation, siehe 2,
2. 2. Eindosieren oder Zirkulation oder Ausblasen in den Tank 5, siehe 3, 3a, 4, 4a,
3. 3. Eindosieren und gleichzeitige Zirkulation oder nur Zirkulation oder Ausblasen in den Tank 5, siehe 5, 5a und 6, 6a, und
4. 4. nach dem Ausblasen in den Tank kann auch wieder in die jeweilige Dosierstellung umgeschaltet werden, in der bei einer Verbindung der ersten Fluidleitung 4 mit der Drucklufteinheit 6 ein Ausblasen des gesamten oder restlichen Leitungssystems erfolgen kann.

According to the invention therefore three different operating options are given:

1. 1. dosing and simultaneous circulation, see 2 .
2. 2. Dosing or circulation or blowing into the tank 5 , please refer 3 . 3a . 4 . 4a .
3. 3. Dosing and simultaneous circulation or just circulation or purging in the tank 5 , please refer 5 . 5a and 6 . 6a , and
4. 4. after blowing into the tank can also be switched back to the respective metering position, in the case of a compound of the first fluid line 4 with the compressed air unit 6 a blowout of the entire or residual line system can take place.

The invention is not limited to the illustrated and described embodiments, but also includes all the same in the context of the invention embodiments. It is expressly emphasized that the exemplary embodiments are not limited to all the features in combination, but rather each individual partial feature may also have an inventive meaning independently of all other partial features. Furthermore, the invention is not yet in the claim 1 defined feature combination limited, but can also be defined by any other combination of certain features of all the individual features disclosed. This means that basically every single feature of the claim 1 omitted or replaced by at least one disclosed elsewhere in the application individual feature.

LIST OF REFERENCE NUMBERS

1

terminal connector

2

connecting channel

3

connecting section

4

First fluid line

4a

Through channel

5

tank

5a

switching valve

6

Compressed air unit

7

connector

7a

receiving opening

8th

Connectors

8a

dosing

9

Second fluid line

9a

Through channel

10

connecting section

11

restriction

12

connector body

12a

grooves

12b

projections

13

peripheral seals

14

closing plate

15

Through openings

15a

Through Hole

15b

Through Hole

16

17

connecting body

18

19

plug pins

20

holding means

21

valve body

21a

compression spring

22

Groove / tongue joint

23

longitudinal bore

24

cross hole

24a

cross hole

25

cross hole

25a

cross hole

26

peripheral seal

27

connecting bore

28

29

cavity

30

circumferential groove

32

open-edge channel

33

communication gap

Claims (24)

Conduit system for SCR applications, comprising a connection connector (1) with a connection channel (2) to which at a channel end via a connection portion (3), a first fluid line (4) is connected to a tank (5) or with a compressed air unit (6) is alternatively connected, wherein the tank (5) is filled with a urea solution, and the connection connector (1) at the other end of the through-channel (2) via a connector (7) and a connector (8) with a metering unit (8a ) is connectable to the injection of the urea solution, characterized in that on the connection channel (2) a second fluid line (9) via a connection portion (10) is connected, which is also connected to the tank (5). According to Claim 1 , characterized in that in the connection channel (2) of the connection connector (1) a valve body (21) in the connection piece (7) integrated valve between two positions of the valve body (21) is adjustably guided, wherein in a first position of the valve body (21 ) the urea solution located in the tank (5) is introduced through the valve body (21) into the connection piece (7) for transfer to the dosing unit (8a) and the second fluid line (4) is closed, and in a second valve body position the first one Fluid line (4) and the second fluid line (9) via the valve body (21) for a circulation of urea solution are connected, and no introduction of the urea solution in the dosing unit (8a) via the valve body (21) takes place, or a blowing out of the first fluid line (4) via the second fluid line (9) into the tank (5). According to Claim 1 , characterized in that in the connection channel (2) of the connection connector (1) a valve body (21) in the connection connector (1) integrated valve is adjustably guided between two valve body positions, wherein in a first valve body position both in the tank (5) urea solution through the valve body (21) into the dosing unit (8a) is introduced, as well as a circulation of the urea solution through the valve body (21) through the second fluid line (9) back into the tank (5), and in a second valve body position only a circulation from the first fluid line (4) through the valve body (21) via the second fluid line (9) back into the tank (5), or a blowing out of the first fluid line (4) via the second fluid line (9) in the Tank (5) takes place. Management system according to one of Claims 1 to 3 , characterized in that the connection connector (1) has electrical heating means. Management system according to one of Claims 1 to 4 , characterized in that the first fluid line (4) and second fluid line (9) distributed over the respective line length have electrical heating means. Management system according to one of Claims 1 to 5 , characterized in that the first fluid line (4) and the second fluid line (9) in each case by welding or gluing in hollow cylindrical receptacles of the sleeve-like connection portions (3, 10) are attached. Management system according to one of Claims 1 to 6 , characterized in that the cross-sectional constriction in the region of the second fluid line (9) is formed by a throttle (11) within the connection section (10) for the second fluid line (9). Management system according to one of Claims 1 to 7 , characterized in that the valve is designed as an electromagnetic valve. Management system according to one of Claims 1 to 8th , characterized in that the valve body (21) is designed as a cylinder, which is mounted translationally and / or rotationally within the connection channel (2) and distributed on the circumference grooves and / or in the valve body (21) formed channels or holes. Management system according to one of Claims 1 to 9 , characterized in that the valve body (21) at least partially made of ferromagnetic material or has a ferromagnetic portion, and on the outside of the connecting body, an electromagnet is attached, which acts on the valve body (21). Management system according to one of Claims 1 to 10 , characterized in that the valve body (21) consists of a material resistant to urea. Management system according to one of Claims 1 to 11 , characterized in that the valve body (21) at its periphery for improving the sliding properties and the media resistance compared to an uncoated valve body has a coating. Management system according to one of Claims 1 to 12 , characterized in that the flow cross section within the connection section (10) for the second fluid line (9) or within the second fluid line (9) in the form of a throttle point (11) is smaller than the flow cross section within the first fluid line (4) with the associated Connection section (3). Terminal connector (1) for use in a piping system according to any one of Claims 1 to 12 consisting of a formed as a plastic molded part connector body (12) having the inner connection channel (2) and the first connection portion (3) for the connection of the first fluid line (4) and the connection piece (7) for the connector (8), wherein the connection section (3) and the connection piece (7) each have a through opening (15) or receiving openings (7a) ending in the connection channel (2), characterized in that between the first connection section (3) and the connection piece (7) a second one Connecting portion (10) is formed on the connector body (12) having a in the connection channel (2) ending through opening (15). Connection connector (1) to Claim 14 , characterized in that within the connection channel (2) a cylindrical valve body (21) in the longitudinal direction of the connection channel (2) between two valve positions is translationally guided, in a first, the connecting piece (7) for the connection of the connector (8 ), and a second position away from the fitting (7), and vice versa. Connection connector (1) to Claim 15 , characterized in that in the valve body (21) in the longitudinal direction of the valve body (21) extending, closed at their ends longitudinal bore (23) is formed, and two transverse bores (24, 25) which are arranged so that they are in the longitudinal direction of the Valve body are arranged one behind the other and on the one hand in the longitudinal bore (23) and on the other hand on the outer periphery of the valve body (21) ends, and in particular between the two transverse bores (24, 25) on the circumference of the valve body (21) has a circumferential seal (26) is arranged , Further, through the valve body (21) through in the longitudinal direction of a connecting bore (27) is formed. Connection connector (1) to Claim 16 , characterized in that the two transverse bores (24, 25) in the valve body (21) are arranged such that their outlet openings in the second position in each case with the passage opening (15) of the connecting portions (3, 10) are connected and in the the first valve body position both transverse bores (24, 25) are closed, and the passage opening (15) of the connecting portion (3) connected to the tank (5) ends in a cavity (29) between the valve body (21) at its from the connecting piece (7) remote end and the opposite wall of the connector body (12) is formed. Connection connector (1) to Claim 15 , characterized in that four transverse bores (24, 24a, 25, 25a) are formed one behind the other, which are connected on one side with the longitudinal bore (23) in the valve body (21), and on the other hand on the circumference of the valve body (21) terminate, in particular a circumferential seal (26) is arranged between the second and third transverse bores (24a, 25) on the circumference of the valve body (21), the first and second transverse bores (24, 24a) being connected to the first fluid conduit (4), and the third and third bores fourth transverse bore (25, 25 a) with the second fluid conduit (9) in dependence on the position of the valve body (21) are connectable. Connection connector (1) to Claim 18 characterized in that the cross-section of the through-hole (15b) of the second fluid line (9) connecting portion (10) is larger than the cross-section of the fourth transverse bore (25a) in the valve body (21) and the valve body (21) is fitted in that, in the second position of the valve body (21), its second transverse bore (24a) communicates with the throughbore (15a) of the connecting portion (3) for the first fluid conduit (4) and the fourth transverse bore (25a) of the valve body (21st) ) with the through hole (15b) for the second connecting line (9) and the through hole (15b) of the connecting portion (10) for the second connecting line (9) via a connecting gap (33) with the connecting channel (2) in the region of the connecting piece (7) for the dosing unit (8a) is formed. Connection connector (1) to Claim 19 , characterized in that the valve body (21) is adapted such that in its first valve body position, the first transverse bore (24) of the valve body (21) with the through hole (15a) of the connecting portion (3) for the first fluid line (4) in connection stands, and the third transverse bore (25) with the through hole (15b) for the second fluid line (9). Connection connector (1) to Claim 18 , characterized in that the valve body (21) is adapted such that in the second, of the connection piece (7) for the dosing unit (8a) remote position of the valve body (21), the first transverse bore (24) with one in the wall of the connector (7) is formed groove-shaped, open-edge channel (32) which extends in the longitudinal direction in the wall of the cavity (29), and the cavity (29) via the connecting bore (27) in the valve body (21) with the connection channel (2 ) in the vicinity of the connecting piece (7) is connected, so that a flow from the connecting portion (3) for the first fluid line (4) is possible up to the metering module, and the fourth transverse bore (25 a) with the through hole (15) of the connecting portion (10) for the connection of the second fluid line (9) is connected, and the third transverse bore (25) through the wall of the connecting piece (7) is closed. Connection connector (1) to Claim 21 characterized in that the valve body (21) is adapted such that in the first valve body position the first transverse bore (24) communicates with the passage opening (15) of the connecting portion (3) for the first fluid conduit (4) and the third one Transverse bore (25) with the passage opening (15) of the connecting portion (10) for the connection of the second fluid line (9) is in communication, and the other transverse bores through the wall of the connector body (12) are closed. Connection connector (1) to Claim 15 , characterized in that on the circumference of the valve body (21) a circumferential groove (30) is formed which has such an axial length that the two through holes (15) of the connecting portions (3, 10) for the fluid lines (4, 9) in the raised second position of the valve body (21) in the circumferential groove (30) terminate, and in the valve body (21) extending therethrough in the longitudinal direction of the connecting bore (27) is provided. Connection connector (1) to Claim 23 , characterized in that in the first position of the valve body (21) the passage opening (15) of the connection section (3) for the first fluid line (4) ends in the cavity (29), and the passage opening (15) of the connection portion (10) for the second fluid line (9) in the circumferential groove (30).

Images